Update: When this paper was published, Lab Land received an email providing anecdotal support for effectiveness in humans. “I have suffered with psoriasis all my life and in 2015, I went on an expedition to Central America. I got eaten alive by fire ants, as they managed to get into my socks. My psoriasis however got better for a time, and as somebody who has directly experienced fire ant venom, I strongly believe that there is a correlation between it and psoriasis.”

The findings could lead to new treatments for psoriasis, a common autoimmune skin disease. Topical steroids are now most frequently used for mild to moderate psoriasis, but they have side effects such as skin thinning and easy bruising.

Solenopsins are the main toxic components of fire ant venom. They chemically resemble ceramides, which are lipid-like molecules essential for maintaining for the barrier function of the skin. Ceramides can be found in many skin care products.

Ceramides can act as a double-edged sword, says lead author Jack Arbiser, MD, PhD, professor of dermatology at Emory University School of Medicine. Under certain conditions they can be converted by cells into S1P (sphingosine-1-phosphate), an inflammatory molecule.

Arbiser and his colleagues devised two solenopsin analogs that look like ceramides, but can’t be degraded into S1P. They then tested them in a mouse model of psoriasis, applying the compounds in a one percent skin cream for 28 days. Read more

Evidence is emerging that naltrexone, a medicine used to treat opioid and alcohol abuse, can also control a genetic skin disease that causes painful, itchy rashes and blisters.

Two separate brief reports last week in JAMA Dermatology, from Emory and Cleveland Clinic investigators, describe the treatment of six patients with Hailey-Hailey disease.

Dermatologist Ron Feldman, MD, PhD is the senior author on the Emory report, which says:

“Low-dose naltrexone has been widely touted on social media platforms, including multiple YouTube videos, as an anecdotal treatment for patients with HHD, with surprisingly no published evidence until this year.”

Feldman tells Lab Land: “We decided to try it based on the patients; we had no clue about low-dose naltrexone until we met one of the patients with Hailey-Hailey disease, who came in asking for this therapy based on social media.”

At Emory, each of the three patients had tried at least four prior treatments, such as antibiotics and corticosteroids, but all were unsuccessful in controlling the disease. Read more

One of the speakers at Thursday’s Antibiotic Resistance Center symposium, Gerald Wright from McMaster University, made the case for fighting antibiotic resistance by combining known antibiotics withÂ non-antibiotic drugs that are used to treat other conditions, which he called adjuvants.

As an example, he cited this paper, in which his lab showed that loperamide, known commercially as the anti-diarrhealÂ Immodium, can make bacteria sensitive toÂ tetracycline-type antibiotics.

Wright said that other commercial drugs and compounds in pharmaceutical companies’ libraries could have similar synergistic effects when combined with existing antibiotics. Most drug-like compounds aimed at human physiology follow “Lipinski’s rule of five“, but the same rules don’t apply to bacteria, he said. What might be a more rewarding place to look for more anti-bacterial compounds? Natural products from fungi and plants, Wright proposed.

“I made a little fist-pump when he said that,” says Emory ethnobotanist Cassandra Quave, whose laboratory specializing in looking for anti-bacterial activities in medicinal plants.

Indeed, many of the points he made on strategies to overcome antibiotic resistance could apply to Quave’s approach. SheÂ and her colleagues have been investigatingÂ compounds that can disruptÂ biofilms, thusÂ enhancingÂ antibiotic activity. More at eScienceCommonsÂ and at her lab’s site.

A paper published Tuesday in Nature Communications from researchers at the University of Chicago shows that honokiol inhibits the mitochondrial enzyme Sirt3, which has connections to longevity.Â Manesh Gupta and colleagues demonstrate thatÂ honokiol canÂ blockÂ cardiac hypertrophy in mice, a finding with possible relevance for the treatment of heart failure.

Sirt3 has been linked both genetically to human life span, and until now, the only way to increase levels of Sirt3 was old-fashioned calorie restriction and/or endurance exercise.

The authors write: It is believed thatÂ Sirt3 does not play a role inÂ embryonic development, but rather it fine tunes the activity ofÂ mitochondrial substrates by lysine deacetylation to protect cellsÂ from stress…Â To theÂ best of our knowledge, this is the first report describing aÂ pharmacological activator of Sirt3.

Nox4 has emerged as a potentialÂ therapeutic targetÂ in ataxia-telangiectasia, a rare multifaceted genetic disorder that leads to neurological problems, a weakened immune system and an increased risk of cancer. Ataxia-telangiectasia (or A-T) is caused by a defect in ATM, a sensor responsible for managing cellsâ€™ responses to DNA damage and other kinds of stress.

In a February PNAS paper, researchers at the National Cancer Institute led by William Bonner reportÂ that a Nox4 inhibitor can dial back oxidative stress and DNA damage in ataxia-telangiectasia cells, and can reduce cancer rates in a mouse model of the disease. Nox4 wasÂ activated in cells and tissue samples obtained from A-T patients.

The Nox4 inhibitor the NCI team used, fulvene-5, was originally identified by Arbiser in a 2009 Journal of Clinical Investigation paper as a possibleÂ treatment for hemangiomas, a common tumor in infants that emerges from blood vessels.

Jack Arbiser, MD, PhD, and colleagues originally isolated honokiol from magnolia cones. It can also be found in herbal teas.

The paper, from Sabrina Diano, Tamas Horvath and colleagues at Yale, probes the role of reactive oxygen species (ROS) in the hypothalamus, a part of the brain that regulates appetite. In the paper, Horvathâ€™s laboratory uses honokiol as a super-antioxidant, mopping up ROS that suppress appetite. Arbiser initiated the collaboration with Horvath after finding, while working with Emory free radical expert Sergei Dikalov, how effective honokiol is at neutralizing ROS.

The paper is intriguing partly because itâ€™s an example of a situation where ROS, often thought to be harmful because of their links to aging and several diseases, are actually beneficial. In this case, they provide a signal to stop eating. A recent paper from Andrew Neishâ€™s lab at Emory provides another example, where probiotic bacteria stimulate production of ROS, which promote healing of the intestine.

Arbiser notes that since honokiol can increase appetite, the compound may be helpful in situations where doctors want patients to eat more.

â€œThis might be particularly valuable in patients who are nutritionally deficient due to chemotherapy and provides a rationale for adding honokiol to chemotherapy regimens,â€ he writes.

Satiety producing neurons in the hypothalamus

A note of caution: in the Nature Medicine paper, honokiol is infused directly into the brain.

Honokiol has been shown to counteract inflammation and slow the growth of blood vessels (important in fighting cancer). Collaborating with Arbiser, Emory endocrinologist Neale Weitzmann has recently found that honokiol stimulates osteoblasts, the cells that build bone, suggesting that it could reduce bone loss in osteoporosis.